Methylisocyanate as an antisickling agent and its reaction with hemoglobin S

Reviewing the reaction of potassium cyanate, an antisickling agent, with alpha-amino groups of hemoglobin, it was found that the reaction was a slow process and requires a large excess of the reagent. The reason for the slow reaction rate of carbamylation of hemoglobin by cyanate is that cyanate itself does not react with hemoglobin. It is rather isocyanic acid, the reactive species, that reacts with hemoglobin. Since the pK of isocyanic acid is 3.8, only one out of 4,000 cyanate ions is present as isocyanic acid at physiological pH. Therefore, it appears that a large excess of cyanate ions is required to achieve the carbamylation of hemoglobin S, both in vivo and in vitro. Furthermore, the pH optimum for carbamylation of carboxyhemoglobin and deoxyhemoglobin is 5.5 and, at pH 7.4, the reaction velocity drops to one-third for carboxyhemoglobin and one-half for deoxyhemoglobin. To seek an approach to reduce the dosage of cyanate and to increase the reaction velocity, an isocyanate derivative, methylisocyanate which is already in the reactive form, was tested for its antisickling activity and its reaction with hemoglobin S. It was found that methylisocyanate had antisickling activity and that only a stoichiometric amount to 2-fold excess of the reagent over hemoglobin S alpha-amino groups was required to prevent the sickling of erythrocytes. Methylisocyanate-treated sickle erythrocytes showed an increased oxygen affinity compared to untreated methylisocyanate reacted with alpha-amino groups of hemoglobin S and the reaction was complete in less than 1 min. Methylcarbamylated hemoglobin S had a higher minimum gelling concentration than the untreated hemoglobin S. There was no detectable reaction of free sulfhydryl and epsilon-amino groups of hemoglobin S with methylisocyanate. These results indicate that methylisocyanate, and probably other isocyanate derivatives, possesses powerful antisickling activity.     

Schiff base adducts of hemoglobin. Modifications that inhibit erythrocyte sickling

Normal and sickle erythrocytes were exposed in vitro to millimolar concentrations of 31 different carbonyl compounds. Schiff base (imine) linkages were formed with amino groups of intracellular hemoglobin. Adducts were isolated by gel electrofocusing and could be dissociated by dialysis. Aromatic aldehydes proved more reactive than aliphatic aldehydes, and ketones were unreactive. The influence of various ring substituents on the reactivity of aromatic aldehydes was found to conform closely to traditional concepts regarding electronic and steric effects. Several of the aromatic aldehydes were shown to markedly increase the oxygen affinity of hemoglobins A and S. In particular, 2,4-dihydroxybenzaldehyde and o-vanillin, at concentrations of 5 mM, produced 2- to 3-fold reductions in the P50 (partial pressure of oxygen at half-saturation) of sickle hemoglobin in whole blood. Since low degrees of oxygen saturation promote erythrocyte sickling, compounds of this type significantly inhibit sickling at reduced partial pressures of oxygen.     

Biotransformation of 4-dimethylaminophenol: reaction with glutathione, and some properties of the reaction products

4-Dimethylaminophenol (DMAP) forms ferrihemoglobin by catalytic transfer of electrons from ferrohemoglobin to oxygen. In solutions of purified human hemoglobin, quick binding of oxidized DMAP to the globin moiety of hemoglobin terminates this reaction. Reduced glutathione in high concentrations, as in the red cell, substantially diminished binding of oxidized DMAP to hemoglobin by formation of S,S,S-(2-dimethylamino-5-hydroxy-1,3,4-phenylene)-tris-glutathione (tris-(GS)-DMAP), which does not form ferrihemoglobin. In the presence of reduced glutathione, DMAP disappeared more rapidly from hemoglobin solutions than in its absence. The formation of tris(GS)-DMAP in red cells was found to be of importance for the termination of catalytic ferrihemoglobin formation by DMAP in vivo. With low concentrations of GSH, DMAP in hemoglobin solutions formed another conjugate, (GS)-DMAP, S,S(2-dimethylamino-5-hydroxy-1,3-phenylene)-bis-glutathione. Similar to DMAP, bis(GS)-DMAP catalyzed the formation of ferrihemoglobin. As the oxidized bis(GS)-DMAP was bound to hemoglobin more slowly and to a lesser extent, it produced more ferrihemoglobin than DMAP. In contrast to the reactions of DMAP with hemoglobin, hydrogen peroxide and superoxide radicals are involved in the ferrihemoglobin formation by bis(GS)-DMAP. The radicals accelerate the oxidation of bis(GS)-DMAP and thereby the ferrihemoglobin formation.     

Effects of the allosteric modification of hemoglobin on brain oxygen and infarct size in a feline model of stroke

BACKGROUND AND PURPOSE: Cerebral ischemia and stroke are leading causes of morbidity and mortality. An approach to protecting the brain during ischemia is to try to increase the delivery of oxygen via the residual blood flow through and around ischemic tissue. To test this hypothesis, we used a novel oxygen delivery agent, RSR-13 (2-[4-[[(3,5-dimethylanilino)-carbonyl]-methyl]phenoxy]-2-methylpr opionic acid). Intravenous administration of RSR-13 increases oxygen delivery through allosteric modification of the hemoglobin molecule, resulting in a shift in the hemoglobin/oxygen dissociation curve in favour of oxygen delivery. METHODS: We studied RSR-13 in a feline model of permanent middle cerebral artery occlusion to assess its effects on cerebral oxygenation and infarct size. A randomized, blinded study of RSR-13 (n = 6) versus 0.45% saline (n = 12) was conducted, after an RSR-13 dose-escalation study (n = 4). Drug was administered as a preocclusion bolus followed by a continuous infusion for the duration of the experiment (5 hours). Brain oxygen was measured continuously with the use of a Clark oxygen electrode. Infarct size was measured at 5 hours after occlusion with computer-assisted volumetric analysis. RESULTS: The drug treatment group had consistently higher mean brain oxygen tension than controls (33 +/- 5 and 27 +/- 6 mm Hg, respectively) and significantly smaller infarcts (21 +/- 9% versus 33 +/- 9%, respectively, P < .008). We observed an inverse relationship between the dose response of RSR-13 (the shift in the hemoglobin/oxygen dissociation curve) and infarct size. CONCLUSIONS: These results are evidence that allosteric hemoglobin modification is protective to the brain after acute focal ischemia, providing a new opportunity for neuroprotection and raising the possibility of enhancing the protective effect of thrombolysis and ion channel blockade.     

Ligand linked assembly of Scapharca dimeric hemoglobin

The assembly of Scapharca dimeric hemoglobin as a function of ligation has been explored by analytical gel chromatography, sedimentation equilibrium, and oxygen binding experiments to test the proposal that its cooperativity is based on quaternary enhancement. This hypothesis predicts that the liganded form would be assembled more tightly into a dimer than the unliganded form and that dissociation would lead to lower oxygen affinity. Our experiments demonstrate that although the dimeric interface is quite tight in this hemoglobin, dissociation can be clearly detected in the liganded states with monomer to dimer association constants in the range of 10(8) M-1 for the CO-liganded state and lower association constants measured in the oxygenated state. In contrast, the deoxy dimer shows no detectable dissociation by analytical ultracentrifugation. Thus, the more highly hydrated deoxy interface of this dimer is also the more tightly assembled. Equilibrium oxygen binding experiments reveal an increase in oxygen affinity and decrease in cooperativity as the concentration is lowered (in the muM range). These experiments unambiguously refute the hypothesis of quaternary enhancement and indicate that, as in the case of human hemoglobin and other allosteric proteins, quaternary constraint underlies cooperativity in Scapharca dimeric hemoglobin.     

钙处理中间产物的形成及其对氧化铝夹杂的改性

通过观测钙处理前后夹杂物形貌和成分的变化,对钙处理效果、中间产物的形成及不同中间产物对氧化铝夹杂的改性路径进行了研究.结果表明,钙处理可将钢液中不规则固态夹杂改性为球形液态夹杂,并且各炉次夹杂物的改性程度不同.热力学分析表明,Als和S含量越高,氧化铝夹杂改性为液态的难度越大.钙处理后的短时间内,Ca S和CaO作为中间产物存在.通过建立中间产物生成的动力学模型,确定了生成不同中间产物的临界硫质量分数为11.1×10^-6（钢液中溶解氧质量分数为4×10^-6）.由该模型结合结果分析,推断出不同中间产物对氧化铝的改性路径.     

Effect of cholecystokinin-pancreozymin (CCK-PZ) on glycoprotein secretion from mouse gallbladder epithelium: an ultrastructural and cytochemical study

L-Azetidine-2-carboxylic acid, the naturally occurring lower homologue of L-proline, is incorporated into hemoglobin S (sickle hemoglobin) in vitro. Sickle erythrocytes from patients with sickle cell anemia incubated with L-[3H] azetidine-2-carboxylate synthesized radiolabeled hemoglobin which when isolated from cell lysates, co-chromatographed with hemoglobin S on DEAE-cellulose columns. The alpha/beta ratio of azetidine carboxylate incorporation into the globin chains of sickle hemoglobin was 0.94, which is consistent with the presence of four proline residues in each polypeptide chain. Incorporation of azetidine carboxylate into hot trichloroacetic acid-insoluble material in sickle erythrocytes indicated that the homologue was present in the polypeptide backbone of the globin chains of sickle hemoglobin. Amino acid analysis of the hot trichloroacetic acid-insoluble material from sickle erythrocytes which had been incubated with radiolabeled azetidine carboxylate indicated that 75% of the radioactivity could be accounted for as intact homologue while 20% of the radioactivity co-chromatographed with alanine. These results suggest that azetidine carboxylate is incorporated unaltered into hemoglobin S in addition to being metabolized to alanine in sickle erythrocytes prior to incorporation into protein. The kinetics of thermal precipitation of hemoglobin S (oxygen ligand) into which radioactive azetidine carboxylate or radioactive proline had been incorporated in vitro is identical. This observation, together with the behavior of hemoglobin S and the globin chains from hemoglobin S containing azetidine carboxylate during ion-exchange chromatography, indicates that homologue replacement of prolyl residues does not significantly alter the overall charge or stability of the hemoglobin S tetramer. Azetidine carboxylate did not inhibit uptake of radiolabeled proline by sickle erythrocytes suggesting that the homologue does not adversely affect amino acid transport in these cells.     

Anionic binding site and 2,3-DPG effect in bovine hemoglobin

It is generally believed that bovine hemoglobin (BvHb) interacts weakly with 2,3-diphosphoglycerate (2,3-DPG) in a chloride-free media and not at all in the presence of physiological concentrations of chloride (100 mM). This lack of interaction has raised several questions at both structural and evolutionary levels. Results obtained in this study via 31P nuclear magnetic resonance (NMR) show that, even in the presence of 100 mM chloride ions, 2,3-DPG does, in fact, interact with bovine deoxy-Hb. This spectroscopic observation has been confirmed by oxygen binding experiments, which have also shown that, under certain conditions, chloride and 2,3-DPG may display a synergistic effect in modifying the oxygen affinity of bovine hemoglobin. It could be that this synergistic effect has its structural basis in a conformational modification induced by 2,3-DPG, possibly causing extra chloride anions to approach the positive charges which constitute the anion binding site. Another possibility, not necessarily an alternative, is the additional chloride binding site recently identified [Fronticelli, C., Sanna, M. T., Perez-Alvarado, G. C., Karavitis, M., Lu, A.-L., and Brinnigar, W. S. (1995) J. Biol. Chem 270, 30588-30592] involving lysine beta76 that in bovine Hb substitutes for the alanine residue present in human hemoglobin. All of these findings are in agreement with the very low enthalpy of oxygenation that characterizes bovine Hb when both chloride and 2,3-DPG are present in concomitance. The results reported here clearly show that bovine hemoglobin does react with 2, 3-DPG and is functionally affected by this organic phosphate. Hence, the very low intraerythrocytic concentration of 2,3-DPG (0.5 mM) in adult bovine red blood cells is the result of metabolic adaptation which cannot be explained solely by the different amino acid sequence at the level of the 2,3-DPG binding site.     

Effect of (-)hydroxycitrate on the activities of ATP citrate lyase and the enzymes of acetyl-CoA metabolism in rat brain

1. (-)Hyrdoxycitrate is a potent inhibitor of ATP citrate (pro-3S)lyase (EC 4.1.3.8) from rat brain, the inhibition being uncompetitive with respect to MgATP2-and competitive with citrate (Ki 0.8 muM). 2. The rate of oxygen consumption by rat brain synaptosomes and the activities of fatty acid synthetase, carnitine acetyltransferase, glucose-6-phosphate dehydrogenase and acetyl-CoA-synthetase are not affected by (-)hydroxycitrate. 3. (-)Hydroxycitrate inhibits the activities of isocitrate dehydrogenase, malate dehydrogenase (decarboxylating) and aconitate hydratase at millimolar concentrations.     

A near-infrared spectroscopic study of cerebral ischemia and ischemic tolerance in gerbils

BACKGROUND AND PURPOSE: To explore the physiological mechanism of ischemic tolerance, we studied intracerebral oxygenation states noninvasively using near-infrared spectroscopy after bilateral common carotid artery occlusion (BCO) in gerbils with and without ischemic pretreatment. METHODS: Under ether anesthesia, gerbils with sham operation (S group, n = 8) and those with pretreatment consisting of BCO for 2 minutes, twice at 3 days and 2 days earlier (T group, n = 8), were again subjected to BCO for 5 minutes. Changes in oxyhemoglobin (HbO2), deoxyhemoglobin (Hb), and total hemoglobin (HbT) as well as reduction in cytochrome oxidase (cyt.aa3) were calculated from the absorbance changes of the light transmitted through the brain. Seven days after the ischemic study, immunohistochemical examination was performed with an antiserum against microtubule-associated proteins. RESULTS: In both groups, the increase of Hb and decrease of HbO2 and HbT proceeded rapidly after BCO, and the maximal deoxygenation of hemoglobin occurred within 2.5 minutes. Reduction of cyt.aa3 also ensued rapidly and reached the maximal reduction within 3 minutes in both groups. In the T group, however, both deoxygenation of hemoglobin and reduction of cyt.aa3 progressed more slowly than in the S group. The time (seconds) necessary for a maximal change for cyt.aa3 was significantly longer in the T group (203.8 +/- 34.0 [mean +/- SD]; P < .01) than in the S group (68.0 +/- 14.7). The time necessary for a half-maximal change was also significantly longer in the T group than in the S group for both Hb (22.0 +/- 7.5 and 13.5 +/- 4.0, respectively; P < .05) and cyt.aa3 (23.9 +/- 5.7 and 11.6 +/- 4.3; P < .01). After recirculation for 7 days, all gerbils in the S group were found to have neuronal death in the hippocampus, while those in the T group did not. CONCLUSIONS: The present study indicated that mild ischemic stress can induce improvement in oxygen metabolism during subsequent ischemia, which might be causally related to the phenomenon known as "ischemic tolerance," in which a protective effect toward ischemic/postischemic injury is induced by earlier mild ischemic pretreatment.     

Lactic acidosis in long-chain fatty acid beta-oxidation disorders

Novel polyamides were developed that can be used as cross-linking agents for proteins such as hemoglobin. Water-soluble, nonimmunogenic polyamides containing oxygen and sulfur atoms in the backbone were prepared by the polycondensation of the diacids bis(carboxymethyloxyacetyl)-1,4-diaminobutane (1a) or 3, 3'-thiodipropionic acid (1b) with diethylene glycol bis(3-aminopropyl) ether (2). The resulting alpha,omega-diacids were converted to the corresponding activated esters using any of a variety of carboxylic acid activating reagents including the novel reagent diphenyl(1-methylimidazol-2-thiyl)phosphonate (9). The resulting polyamides could be activated with a broad spectrum of groups that allow for the cross-linking and surface modification of proteins.     

Capillary oxygen transport during severe hypoxia: role of hemoglobin oxygen affinity

The efficacy of an increased hemoglobin oxygen affinity [decreased oxygen half-saturation pressure of hemoglobin (P50)] on capillary oxygen transport was evaluated in the hamster retractor muscle under conditions of a severely limited oxygen supply resulting from the combined effects of a 40% reduction in systemic hematocrit and hypoxic ventilation (inspired oxygen fraction 0.1). Two groups of hamsters were utilized: one with a normal oxygen affinity (untreated; P50 = 26.1 +/- 2.4 Torr) and one with an increased oxygen affinity (treated; P50 = 15.7 +/- 1.4 Torr) induced by the chronic short-term administration of sodium cyanate. Using in vivo video microscopy and image analysis techniques, we determined oxygen saturation and associated hemodynamics at both ends of the capillary network. During hypoxic ventilation, the decrease in oxygen saturation across the network was 3.6% for untreated animals compared with 9.9% for treated animals. During hypoxia, estimated end-capillary PO2 was significantly higher in the untreated animals. These data indicate that, at the capillary level, a decreased P50 is advantageous for tissue oxygenation when oxygen supply is severely compromised, because normal oxygen losses in capillaries are maintained in treated but not in untreated animals. The data are consistent with the presence of a diffusion limitation for oxygen during severe hypoxia in animals with a normal hemoglobin oxygen affinity.     

Relationships between blood oxygen parameters in patients with chronic obstructive lung disease

The hemoglobin-oxygen dissociation curve and the relationships between the parameters of tension, saturation, capacity, affinity and concentration of oxygen in the course of respiratory failure in chronic obstructive lung diseases (COLD) were studied. The study included 141 patients divided into four basic groups according to the value of pO2 (a): patients with normoxia, mild, moderate and severe arterial hypoxia. The blood-gas status was determined using the ABL-330 and OSM-3 analyzers (Radiometer A/S, Denmark). It is concluded that: 1. Presence of normoxia (pO2 and sO2 in norm) in COLD patients does not exclude abnormalities in their arterial blood oxygen transport and increased risk of tissue hypoxia. 2. Total oxygen concentration in respiratory failure is relatively stable and "independent" from the stepwise decrease of the arterial pO2, which results from the compensatory increase of the total and effective hemoglobin. 3. There are phase fluctuations of the ctO2/pO2 dissociation curve in the reference interval, expressed in the "lowering" of P50 and p90 in mild hypoxia and the "centering" or "raising" of their values in severe hypoxia. Such fluctuations are more pronounced in the p90 than in the p50. 4. The oxygen extraction tension lowers progressively (without reaching the anaerobic threshold) and the oxygen compensation factor elevates with the pO2 (a) reduction and the arising of hypercapnia and acidemia. 5. The calculated 2,3-diphosphoglycerate (2,3-DPG) concentration values are significantly higher in hypercapnics with COHb > 1% than in those with COHb < 1%. The relationships between hypoxia, oxygen affinity, hemoglobinemia and oxygen affinity as well as the dissociation curve properties in chronic respiratory failure are discussed.     

Growth control mechanisms in multiple myeloma

Neo red cells (NRCs) are a blood substitute representing stroma free hemolysate (SFHL) encapsulated in liposomes and containing NAD, glucose, adenine, and inosine, etc. as substrates or coenzymes of the Embden-Meyerhof pathway in RBCs and inositol hexaphosphate (IHP) as an allosteric effector. The oxygen transport efficiency (OTE) of NRCs was increased to > 45% when the oxygen partial pressure in arterial blood increased. We carried out exchange transfusion with NRCs in rats, monitored their functioning as a blood substitute in vivo, and demonstrated that NRCs worked sufficiently. First, we confirmed that the OTE of NRCs was augmented by increasing the oxygen supply to the rats by using oxygen masks. Second, we carried out 70% blood exchange with NRCs (with hemoglobin concentrations of 4, 5, 6, or 7 g/dl), and compared these experimental groups with control groups (RBC and saline). Each sample was contained bovine albumin (final volume of 5% (w/v)). As a result, the NRC groups with hemoglobin concentrations of 5, 6, and 7 g/dl showed stability after the exchange transfusion. On the other hand, the NRC group with hemoglobin concentration of 4 g/dl and the saline group showed respiratory acidosis and a drop of blood pressure and heart rate, and thus did not maintain an adequate oxygen supply. We concluded that a hemoglobin concentration of > 5 g/dl was sufficient in the NRC solution, and demonstrated in an experiment on animals that the OTE of NRCs was increased by using oxygen masks.     

Methemoglobinemia induced by an over-the-counter medication

OBJECTIVE: To report a case of methemoglobinemia induced by benzocaine and resorcinol (Vagisil) cream, an over-the-counter medication that was used to treat diaper rash in a neonate. CASE REPORT: A 6-day-old, 3350-g white boy was found to be cyanotic with blue mucous membranes on presentation. He had a diaper rash that was red and irritated, which his mother had treated with Vagisil cream. Methemoglobinemia secondary to absorption of benzocaine and resorcinol (1,3-benzenediol) from the Vagisil was diagnosed, with a methemoglobin level of 35% on admission (normal 0.4-1.5). Intravenous methylene blue 3 mg (1 mg/kg) was given; the neonate's skin color returned to normal 45 minutes after the dose. DISCUSSION: Methemoglobinemia is a condition in which hemoglobin is oxidized to the ferric form. Oxidized hemoglobin, methemoglobin, is incapable of reversibly binding oxygen at the physiologic partial oxygen pressure. Main causes of methemoglobin formation are exposure to certain oxidizing agents and drugs, deficiency of one of the enzymes necessary for reduction of methemoglobin to hemoglobin, or the presence of an abnormal hemoglobin resistant to reduction. Clinical manifestations of methemoglobinemia include diffuse slate-gray cyanosis with low oxygen saturation in the absence of respiratory distress. A single intravenous dose of methylene blue 1-2 mg/kg is the treatment of choice. CONCLUSIONS: Newborn infants are at increased risk for methemoglobinemia due to diminished enzyme systems required to reduce ferrihemoglobin to ferrohemoglobin, as well as because fetal hemoglobin is more easily oxidized than is adult hemoglobin. It is important to recognize possible drug reactions and educate parents on the potential risks of treatment with over-the-counter medications, especially in neonates.     

The NH2-terminal region of the sickle hemoglobin beta chain. II. Characterization of monospecific antibodies

We have previously shown that antibodies specific for hemoglobin S could be fractionated by absorption of an antiserum to hemoglobin S to Sepharose containing a synthetic oligopeptide. betaS (1-13), corresponding to the first 13 amino acid residues of the beta chain of hemoglobin S. We report here that this antibody population, anti-betaS (1-13), shows considerable restriction of heterogeneity in isoelectric focusing studies and monospecificity on velocity ultracentrifugation in the presence of hemoglobin S. The binding of various hemoglobin species to anti-betaS (1-13) was studied using a double antibody radioimmunoassay with [14C]carbamoylated hemoglobin S. Carbonmonoxy-, oxy-, met-, and cyanmethemoglobin S reacted equally with the antibody, but deoxyhemoglobin (with or without organic phosphates) reacted differently. Hemoglobin A and several hemoglobin mutants with alterations in the NH2-terminal region of the beta chain did not displace labeled hemoglobin S from anti-betaS (1-13). BETAS chains reacted with the antibody, but less well than hemoglobin S, while betaA and alpha chains, and globins did not react with the antibody. The synthetic peptide, betaS (1-13), used for fractionation, reacted with the antibody about 300-fold less efficiently than hemoglobin S. BetaS (3-13) was even less reactive, while smaller peptides which included the valine residue at position 6 displaced little of the tracer [14C]carbamoylated hemoglobin S at concentrations as high as 10(-2) M. We interpret these results to indicate that this method of immunoabsorption has produced a monospecific subfraction of antibodies which is specific for the NH2-terminal region of the beta chain of hemoglobin S in its native conformation.     

Increased thrombosis incidence in a family with an inherited protein S deficiency and a high oxygen affinity hemoglobin variant

Inherited protein S deficiency and the presence of a rare high oxygen affinity hemoglobin variant: Hb Rainier [beta 145 (HC2) Tyr-->Cys] were found in a family. Among 16 studied members, nine were found as carriers of protein S deficiency (type I with decrease of total, free, and activity levels). Six subjects carried the high-affinity hemoglobin variant, which displayed an increase of blood viscosity. Four members combined both abnormalities. Three had thrombotic accidents before the age of 30. We suggest the combination of protein S deficiency and the presence of this hemoglobin variant can lead to a severe primary hypercoagulable state with pathological consequences compared to each genetic defect alone.     

Effect of thiol reagents on functional properties and heme oxidation in the hemoglobin of Geochelone carbonaria

The reaction of thiol reagents with G. carbonaria hemoglobin was studied, and the oxygen equilibrium and kinetic of oxidation of derivatives determined. The oxygen affinity and kinetic of oxidation of hemoglobin derivatives were modified to various extents depending on the nature of thiol reagents used. Diamide yielded approximately 80% polymeric hemoglobin, although the oxidation kinetic, and the functional properties, were practically invariant (T1/2 = 10.0 min.; P50 = 5.0 mm Hg at pH 7.4; alkaline Bohr effect = -0.64). Iodoacetamide did not modify the electrophoretic pattern significantly, although all the free SH groups of hemoglobin were alkylated. A P50 of 2.5 mmHg at pH 7.4 and the Bohr effect of -0.15 were obtained; the T1/2 of about 6.4 min. was shorter than that for un-modified Hb. Similar T1/2 were obtained for Hb treated with oxidized glutathione, which produced polymeric Hb and glutathionyl-Hb. The oxygen binding characteristics showed that both of Hb derivatives, glutathionyl-Hb and polymeric Hb, maintain the capacity to transport the gas.     

Hemoglobin values: comparative survey of the 1976 Canadian Olympic team

In view of the role of hemoglobin in oxygen transport, the hemoglobin concentration in whole blood may indicate readiness for maximal physical performance. Hemoglobin concentrations were determined in members of the 1976 Canadian Olympic team and compared with those of the 1975 Canadian general population and with published data for the 1968 Australian and Dutch Olympic teams. The mean hemoglobin concentrations of the 123 male and 64 female Canadian Olympic athletes were 14.7 +/- 1.0 and 12.9 +/- 0.7 g/dL, respectively. Both male and female Canadian Olympic athletes had significantly lower (P less than 0.01) values than the other three groups. The suboptimal hemoglobin concentrations may be related to inadequate dietary intake of protein and iron.     

Gas exchange and hemodynamics following complete replacement of blood with a solution of purified hemoglobin

Complete exchange blood substitution (down to hematocrit level of 1--3%) by 7--8% solution of hemoglobin (Hb) completely free of stromas and procoagulant activity of human hemoglobin was performed in cats. The Hb solution is capable of carrying oxygen and maintaining the life of the animal with a complete blood loss for some time. The Hb solution is readily saturated with oxygen in the lungs and releases oxygen in the tissues, although to a significantly lesser degree than Hb in the red cell; besides, the Hb solution maintains the basic value of hemodynamics for some time.